Prof A Suhrbier is the Group Leader of the Inflammation Biology Group at the Queensland Institute of Medical Research. The group focuses at the applied end of inflammation research and development and will be involved in the identification and development of new interventions and diagnostics for inflammatory diseases and cancer, often in collaboration with the biotech industry.
Isoform Selective PI3 Kinase Inhibitors For Cancer, Thrombosis And Inflammatory Disease
Funder
National Health and Medical Research Council
Funding Amount
$474,473.00
Summary
Inhibitors of the PI3 kinase family of enzymes have potential as therapeutics in diseases such as cancer, thrombosis and inflammatory disease. In this project the investigators will develop a new class of PI3 kinase inhibitors they have discovered, optimizing their pharmaceutical properties and evaluating them in models of disease. The aim is to develop a candidate for human clinical studies.
We recently discovered a new way to treat melanoma by inhibiting a protein called MDM4 that is important in promoting tumor growth in ~2/3 of melanomas. In this proposal, we will extend this work to see if anti-MDM4 therapy is effective in laboratory models that are more relevant to patients and in combination with other melanoma therapies. We will also explore additional ways of inhibiting MDM4 that may make anti-MDM4 therapy even more potent.
Copper-ionophores As A Treatment For Prostate Cancer?
Funder
National Health and Medical Research Council
Funding Amount
$314,154.00
Summary
The overarching aim of this project is to evaluate a potential therapy for prostate cancer, which targets a distinct characteristic of the disease 'elevated copper'. Our copper-based drugs in the laboratory selectively destroy cancerous prostate cells without harming normal cells. We will verify whether these drugs work in the body where the environment is more complex. Proof of this principle will open up a new area of research and provide a novel therapeutic approach for prostate cancer.
Apoptosis And Stem/Progenitor Cells In The Development And Treatment Of Cancer
Funder
National Health and Medical Research Council
Funding Amount
$21,809,604.00
Summary
To improve cancer therapy, we are studying two cancer hallmarks. The first is excessive cell survival. To combat this, we are developing drugs with commercial partners that directly activate the cell's death machinery. The second hallmark is inexorable proliferation, akin to that of stem cells, which can generate entire tissues, as we showed for the breast. ‘Rogue’ stem-like cells may initiate certain cancers. We hope to advance cancer therapy by identifying such cells and drugs that kill them.
The 3-dimensional Structure Of Anticancer Drug-DNA Complexes Determined By X-ray Crystallography
Funder
National Health and Medical Research Council
Funding Amount
$264,358.00
Summary
Our main objective is to discover the molecular details of how cancer drugs interact with DNA and how these interactions differ from those of inactive chemically related compounds. We propose to use X-ray crystallography together with the successful methods we have developed for determining the 3-dimensional structures of the DNA complexes of a class of antitumour active drugs to study the complexes of other clinically or scientifically important DNA intercalating anticancer drugs. These agents ....Our main objective is to discover the molecular details of how cancer drugs interact with DNA and how these interactions differ from those of inactive chemically related compounds. We propose to use X-ray crystallography together with the successful methods we have developed for determining the 3-dimensional structures of the DNA complexes of a class of antitumour active drugs to study the complexes of other clinically or scientifically important DNA intercalating anticancer drugs. These agents act by poisoning the DNA binding enzyme topoisomerase. Crystallographic analysis will give us unequivocal answers at the atomic level as to the exact way in which the drug binds to DNA and how this binding differs between antitumour active and inactive compounds. We believe that a knowledge of the DNA binding mode of a class of intercalating anticancer drugs at the atomic level is valuable in guiding drug design within that class.Read moreRead less
Development Of Novel And Selective Anticancer Drugs Derived From Cysteine.
Funder
National Health and Medical Research Council
Funding Amount
$264,250.00
Summary
In the next few years cancer is projected to become the leading cause of death in industrialised countries. Cancer chemotherapy currently relies on destruction of tumours by toxic drugs that indiscriminately kill all cell types, resulting in side effects that limit treatment. In the 21st century new cancer drugs will more effectively destroy malignant tumour cells without damaging normal cells. The R and D herein will value-add to our discovery of a new class of potent and orally active anti-tum ....In the next few years cancer is projected to become the leading cause of death in industrialised countries. Cancer chemotherapy currently relies on destruction of tumours by toxic drugs that indiscriminately kill all cell types, resulting in side effects that limit treatment. In the 21st century new cancer drugs will more effectively destroy malignant tumour cells without damaging normal cells. The R and D herein will value-add to our discovery of a new class of potent and orally active anti-tumour drugs that possess unusually high selectivity in acting on cancer cells without killing normal human cells. Our current proof of concept will be turned into a drug development candidate that will improve our negotiating position with commercial partners.Read moreRead less
Molecular Targeting To Telomerase And Cancer Cell Immortality By A Novel Inhibitor
Funder
National Health and Medical Research Council
Funding Amount
$430,812.00
Summary
Infinite growth of cancer cells is a hallmark of cancer. Telomerase is required for cancer cell immortality. Inhibition of telomerase may thus offer an opportunity to stop cancer cells. We have identified an inhibitor of telomerase. This project will study the mechanisms of action of the novel inhibitor, investigating how to control cancer cell immortality as a baseline for more applied anti-cancer therapeutic studies.
Real-time Imaging Of Cell Cycle Progression In Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$526,911.00
Summary
Melanoma is the most aggressive skin cancer and is highly therapy resistant, reasons of which are poorly understood. Here we hypothesise that differences in the growth capacity of melanoma cells in different tumour regions contribute to therapy resistance. We will use a novel microscopic system that allows us to visualise division of individual melanoma cells in intact tumours in real time. Using this system, we will test the effects of targeted therapies on melanoma cell growth and survival.